EE470 Class Homepage

Bulletin Description:

Models for biomedical systems.Non-deterministic nature of biomedical signals, physiological systems and quantitative analysis. Feedback systems, transfer functions and stability.  Frequency response of systems and circuits, and Bode diagrams. A/D conversion, sampling, and discrete-time signal processing. Biomedical amplifiers, filters, signal processors and display devices. Power supplies for medical equipment. Laboratory and computational experiences with biomedical applications. Term project.

Prerequisites: EE 253, EE 301, EE 370

Textbooks: M.J. Roberts, Signals and Systems, Analysis Using Transform Methods and MATLAB, McGraw-Hill, 2004.

References: A.V. Oppenheim, A.S. Willsky, I.T. Young :Signals and Systems, Prentice - Hall, 2nd ed 1996;

E.N. Bruce: Biomedical Signal Processing and Signal Modeling, Wiley 2001;

D.K. Lindner: Introduction to Signals and Systems, McGraw-Hill, 1999.

Instructor:

Dr Nazeeh Alothmany,
email:nothmany@kau.edu.sa,
http://nothmany.kau.edu

Course Topics:

A tentative timetable will be prepared with details of topics after the pretest

Month	Day	Date	Class Topics	Lab Time
Mar-11	Tue	1	IEEE Code of Ethics; EE470 ABET; Introduction to Signals	Lab Report Cover Sheet Lab Guidelines in Arabic
	Sun	6	Mathematical Rep of Signals	Measurements and Errors
	Tue	8	Mathematical Rep of Signals
	Sun	13	Description and Analysis of Systems	Tutorial
	Tue	15	Description and Analysis of Systems
	Sun	20	Description and Analysis of Systems	Digital Thermometer
	Tue	22	Description and Analysis of Systems
	Wed	23	Exam I
	Sun	27	Fourier Series and Transform	Tutorial
	Tue	29	Fourier Series and Transform
Apr-11	Sun	3	Fourier Series and Transform	Frequency Responses Of  1st Order systems
	Tue	5	Exam II
	Sun	10	Vacation
	Tue	12	Vacation
	Sun	17	Fourier Transform	Transients in Linear Systems (RC circuits)
	Tue	19	Tutorial
	Sun	24	Fourier Transform	Fourier Analysis of Signals and Systems
	Mon	25	Midterm
	Tue	26	Fourier Analysis of Signals and Systems
May-11	Sun	1	Fourier Analysis of Signals and Systems	Frequency Responses of 2nd Order systems
	Tue	3	Fourier Analysis of Signals and Systems
	Sun	8	Fourier Analysis of Signals and Systems	Transients in Linear Systems (RLC circuits)
	Tue	10	Sampling and the Discrete Fourier Transform
	Sun	15	Sampling and the Discrete Fourier Transform	Exam III
	Tue	17	Laplace Transform
	Sun	22	Laplace Transform	Twin-T and Lead-lag networks
	Tue	24	Laplace Transform Analysis of Signals
	Wed	25	Exam IV
	Sun	29	Laplace Transform Analysis of Signals	Twin-T and Lead-lag networks
	Tue	31	Laplace Transform Analysis of Signals
Jun-11	Wed	1	Exam V
	Thu	2	Final Exams Begin
	Sun	5	Project Presentations
	Tue	7	Project Presentations
	Tue	14	EE470 Final Exam 10:30-12:30 PM BME LAB

Course Learning Objectives (CLO)

After finishing the course successfully, the BME student shall

1. Express signals in terms of basic signal components in time domain
2. Recognize transformations of continuous-time (CT) and discrete-time (DT) functions
3. Identify real and complex exponential CT and DT functions
4. Sketch signals and system responses (using MATLAB®)
5. Recognize periodicity and identify harmonics of CT and DT functions
6. Identify and use impulse and signals derived from it
7. Generate a signal from its harmonics (using MATLAB®)
8. Describe systems using differential/difference equations
9. Compute the impulse response of the system given the differential/difference equation
10. Compute the output of a system for a given input and its impulse response
11. Describe systems using block diagrams and transfer functions
12. Infer transfer functions from block diagrams and differential/difference equations and vice versa
13. Produce the frequency response function from the transfer function
14. Infer output from the transfer function and input
15. Predict bounded input bounded output stability of a linear time-invariant system
16. Compute continuous and discrete-time Fourier transforms
17. Sketch Fourier transform and frequency response plots using MATLAB®
18. Develop the frequency response function from the Bode plots
19. Compute system parameters from step and sinusoidal frequency response plots
20. Solve mathematical problems using MATLAB®
21. Formulate system characteristics in MATLAB®
22. Design a biomedical signal processor to extract a feature from the raw biomedical signal
23. Use experiments to find transient, steady state and frequency responses of first and second order systems
24. Identify transfer function model for a given system and asses the time and frequency behavior of the system 
25. Assess affects of sampling rate in generating the discrete-time signals and estimate the proper sampling frequency
26. Predict the number samples needed to study a continuous-time signal and choose a proper window function
27. Analyze problems in a team work setting and evaluate the performance of team members
28. Illustrate results and solutions in a written report
29. Orally present and defend his solutions
30. Demonstrate independent problem solving and life-long learning skills
31. Statistically analyze data